机器人形态的现实世界演变：概念验证

Real-World Evolution of Robot Morphologies: A Proof of Concept.

作者信息

Jelisavcic Milan, de Carlo Matteo, Hupkes Elte, Eustratiadis Panagiotis, Orlowski Jakub, Haasdijk Evert, Auerbach Joshua E, Eiben A E

机构信息

Vrije Universiteit Amsterdam, Amsterdam, Netherlands. E-mail:

Universiteit van Amsterdam, Amsterdam, Netherlands.

出版信息

Artif Life. 2017 Spring;23(2):206-235. doi: 10.1162/ARTL_a_00231. Epub 2017 May 17.

DOI:10.1162/ARTL_a_00231

PMID:28513201

Abstract

Evolutionary robotics using real hardware has been almost exclusively restricted to evolving robot controllers, but the technology for evolvable morphologies is advancing quickly. We discuss a proof-of-concept study to demonstrate real robots that can reproduce. Following a general system plan, we implement a robotic habitat that contains all system components in the simplest possible form. We create an initial population of two robots and run a complete life cycle, resulting in a new robot, parented by the first two. Even though the individual steps are simplified to the maximum, the whole system validates the underlying concepts and provides a generic workflow for the creation of more complex incarnations. This hands-on experience provides insights and helps us elaborate on interesting research directions for future development.

摘要

使用真实硬件的进化机器人技术几乎一直局限于进化机器人控制器，但可进化形态学技术正在迅速发展。我们讨论了一项概念验证研究，以展示能够进行繁殖的真实机器人。按照一般的系统计划，我们实现了一个以尽可能简单的形式包含所有系统组件的机器人栖息地。我们创建了由两个机器人组成的初始群体，并运行一个完整的生命周期，从而产生了一个新机器人，其“父母”是最初的两个机器人。尽管各个步骤已被最大限度地简化，但整个系统验证了基本概念，并为创建更复杂的实体提供了通用的工作流程。这种实践经验提供了深刻见解，并有助于我们阐述未来发展中有趣的研究方向。

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机器人形态的现实世界演变：概念验证

Real-World Evolution of Robot Morphologies: A Proof of Concept.

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